DE2262507C3 - Process for producing an identification card - Google Patents

Description

The invention relates to a method for producing an identification card bearing an image of the holder.

The term "ID card" is intended to encompass all types of cards used for identification and / or legitimation of a person can be used, e.g. identity cards, ID cards that allow access to certain buildings, but also credit cards.

It is known in the field of electrophotography to use a translucent plate prior to the electrophotographic plate Arrange grids in order to improve the tonal gradation of the image in this way (US-PS 25 98 732).

Furthermore, a shadowing member can be used in an electrophotographic copier which has an arrangement of parallel, opaque »iger lines that the light in a line-halftone pattern subdivide (DE-AS 12 04 066). A grid pattern is particularly suitable for this. To this You can use continuous tinted images as well as images with contiguous, black areas be generated.

In another known method of electrophotographically producing an image from A raster-like surface pattern is applied to an original, so that the imagewise exposure of the photoconductive layer does not take place in all places, but rather between the imagewise exposed areas unexposed areas are located, the charge of which corresponds to the original charge (DE-AS 12 90 815).

It is also known to be electrostatic, latent Develop the image by means of a fixing agent, which also acts as a protective layer for the finished Figure serves (DE-OS 20 25 090).

Finally, there is another method of transferring an electrostatic charge image from one photoconductive recording medium on a dielectric carrier known (DE-OS 14 72 978), whereby a Cleaning of the photoconductive layer is no longer necessary.

On the ID cards that have been used up to now, the images of the holder are represented by photographs, i.e. in generally by a silver salt process. manufactured.

However, these processes are time-consuming and complicated because they involve several chemical process steps required are. In addition, the process of developing the picture from negative to finished print relatively long.

The instant photo processes sometimes also used to produce the image of the owner are both in terms of camera equipment required and in terms of cost per print relative expensive, so that the speed with which an image of the owner is available has to be bought at a high price got to.

The invention is therefore based on the object of providing a method for producing identification cards specified genre to create that essential

is simpler, more economical and therefore cheaper than ι lie previously used, photographic process is.

According to the invention, this object is given by what is stated in the characterizing part of the patent claim Features solved.

The advantages achieved with the invention are based on a particularly useful combination of several features known for themselves in different areas, all of which are very inexpensive Carry an ID card with a sufficiently clear image of the holder.

Because first of all, the halftone process used enables the production of an electrostatic, latent image of a quality as it is for the Images on identification cards is required.

This latent image is not developed into a visible image on the photoconductive layer itself, but first transferred to a dielectric layer, on which the development is then carried out. This has the essential advantage that there are only latent images on the photoconductive layer are generated so that this sensitive, photoconductive layer is not required for development Comes into contact with toner particles. Because when developing the latent image on the photoconductive The layer itself would have to be cleaned after development has been completed, which required a separate cleaning device for the surface of the photoconductive layer power. However, this would be associated with a large outlay in terms of equipment, with the additional small one The size of an identity card must be taken into account, which is the handling of the material difficult during cleaning. In addition, the material for such an identification card is not so flexible such as paper or other sheet-like materials, which also creates difficulties in cleaning were revealed. And finally, the photoconductive layer has a relatively long life since as mentioned, it does not come into contact with the toner particles.

A transparent card is placed on the finished ID card with the image of the owner Protective layer applied to protect the ID card against damage. Also prevents a appropriately selected protective layer also any manipulation of the information on the identity card Information as it is essential from the point of view of the »forgery-proof identity card«.

The invention is based on a

H ^r > preferred embodiment explained in more detail, for which reference is made to the drawings. F sharp shows

F i g. 1 a cutaway view! an embodiment of the Identity card according to the invention: and

F i g. 2 to 9 representations of the individual process steps for producing the identity card according to FIG Invention.

In Fig. 1 is a base for the identity card according to the invention with a carrier 1 in sheet form or in the form of a thin plate made of paper or a synthetic resin, on which an electrically conductive layer 2 by vapor deposition of aluminum A dielectric layer 3 made of acrylic resin, methacrylic resin, vinyl chloride and the like is formed applied to the electrically conductive layer. The dielectric layer 3 can be scattered or Spread zinc oxide, poly-N-vinyl carbazole or other photoconductive material in a binder be educated. The carrier 1 can be in the form of a metal sheet or an electrically conductive rubber plate have, so that the carrier 1 and the electrically conductive layer 2 together form a unit.

A toner image 4 as shown in FIG. 8 is shown, is formed by means of a ski ^r mgitters or network, as formed in the halftone dots on the dielectric layer. 3 The toner image is, as described below, formed or developed on the dielectric layer of the base. The dielectric layer is brought into contact with a sheet of photoconductive material on which an electrostatic latent image of a person is projected by means of a through-fine Transverse lines of a divided screen are formed, whereby the electrostatic latent image is transferred to the dielectric layer; the electrostatic latent image on the dielectric layer is developed with a toner or other developer.

Image 4 can be copied from a photo print, from a photo or from a picture of a Person is made, and need not be a photo taken directly of a person. Any of that known method is then used to form an electrostatic latent image on the dielectric Layer of underlay used. For example, a pattern or relief of electrically charged Areas on a photosensitive screen, divided by fine transverse lines, by displaying the subjecting an original to electrical charge and exposure of the optical image; an electrostatic latent image is then formed on the dielectric layer of the substrate as a result of the Current of ions generated by corona discharge by means of the mesh grid or screen as a function of is controlled by whether or not different areas on the screen are electrically conductive.

If the dielectric layer on the base has a photoconductive layer, it can be directly the electrical charge and exposure of an image of a person. In any case, one must go through fine cross-lines divided screen are used at the right time during the procedure, to create the halftone effect.

F. a required entry 5 can be made on the dielectric layer after d? s picture 4 is applied; a clear protective layer 6 is provided on the dielectric layer 3 after a stamp is pressed and Letters or other characters are written on it if necessary. In this way the in hS F i g. I received the ID card shown.

F.inc protective layer 6 can be created in that the αίεΙείΊ; ischc layer 3 with a Coated synthetic resin film or a coating of synthetic resin on the electrical layer 3 by means of a Synthetic resin solution is applied or the substrate is immersed in such a solution d.

The method for producing the identification card according to the invention is described in the following step for Step with reference to the figure? to 9 described.

In the procedural step shown in Figure 2, a photoconductive layer 22 is formed on a substrate 21 made of aluminum, copper or another electrically conductive material in that selenium, zinc oxide, poly-N-vinyl carbazole or another conductive material, for example through it Vacuum evaporation is applied, whereby a photosensitive sheet 23 is provided. The photosensitive sheet 23 is subjected to a corona discharge by a charger C with a wire electrode C2 which is connected to a high voltage source C \ which is moved in the direction of an arrow a so as to make the entire surface r- ·. <· Photoconductive

tn-UIClll AA UL3 IUlU3Lll3lll »\. ll UiaiK.3 L · ^ g'I.ILIllt; i llltg iU load. A high bias voltage of a certain polarity (positive in the case of selenium), which is compatible with the charging properties of the photoconductive bar 22, is impressed on the wire electrode C2 , so that the photoconductive layer 22 is charged accordingly. A bias having a polarity opposite to that of layer 22 can be applied to substrate 21, or layer 21 can be grounded as shown. A corresponding insulating plate, not shown, can be attached to the support 21 as a base, or the support ¹ · 21 can, if necessary, be provided with a frame.

In the one shown in FIG. 3, a screen or screen grid 24 is arranged in front of or in the vicinity of the photoconductive layer 22 in order to apply a charge to the entire surface formed in the preceding process. The Sch ^: rm b? ». ·. the screen grid may comprise an insulating plate made of a synthetic resin material, in which a large on the mold; - very small openings are provided M, or the screen may be in the form of a fine subdivided by transverse lines or strips glass plate. The screen or the screen grid is used to generate an image in halftone in the following, third process step, as will be described below. The mesh size of the screen grid is determined or determined by the fact that the points formed by the screen grid must have a size that is below the resolution of the eyes when viewed in a distance of about 25 cm.

In the in Fi g. 4, an image of a person 26 is projected through an objective 25 via the screen or screen grid 24 onto the photoconductive layer 22. The time during which a diaphragm 27 is kept open is less than Vjo sec .. which is taken into account. that the person can move. For this reason, the sensitivity of the photoconductive layer 22 must be increased to a sufficiently high level by adding a dye or other sensitivity-improving agent. The distance / wipe the screen or screen grid 24 and the photo! Eit ^r ähigen layer is determined dauürch b. * ,. stipulates that the screen grid 24 is printed b / w on the photoconductive layer. is reproduced. This exposure can be done by means of

a corresponding validation or copy setup can be done when a picture is taken Person is copied from a print representing them.

In the one shown in FIG. Process step IV shown in FIG. 5 is a blanket layer 28 on which a dielectric layer 29 is applied. placed on the photoconductive layer 22 of the photosensitive sheet 23, on which an electrostatic, latent image is formed or represented by exposure of an image of the person 26. The electrostatic latent image is transferred to the dielectric layer 29 of the substrate by being brought into contact with and separated from it again. The substrate 28 has a carrier 30 and an electrically conductive layer 31 which corresponds to the aforementioned carrier 1 and the electrically conductive layer 2; the dielectric layer 29 is formed on the conductive layer 31. The description of the document 28 can be omitted here, since it is the Unier! S ^CT £ eier in Fi ".! Dsr" ^ '** !! ****! Ancvy ^ jcirartp corresponds, from which the protective layer 6, the toner image 4 and the entry 5 is removed. When the two layers 22 and 29 are brought into contact with each other, sufficient transfer of the electrostatic latent image can be effected by applying appropriate pressure by means of the finger or a roller. The electrically conductive layer 31 is grounded in a known manner.

In step V shown in Fig. 6, the substrate 28 on which the electrostatic latent image is transferred is moved in the direction of an arrow b by a corresponding conveyor, not shown, and its dielectric layer is in contact with the periphery of a rotating one A developing roller 34 made of metal or rubber, a part of the peripheral surface of which is immersed in a developing liquid 33 in a container 32, is brought. The toner in the liquid developer wedge then adheres to the static latent image and converts it into a visible toner image 35. Any known electronic photographic development process with a dry or wet developer can also be used instead of the development process described Toner in the developer contains very small powder particles that are created by processing RuU or other pigment together with a resin.

In the one shown in FIG. 7 is shown method step V1 the toner image developed on the base 28 by heat when a dry developer is used. and fixed by blowing with a stream of air when a wet developer is used.

In rlpm in P j π R <v * i7 «MiTt *> n ancestor duty VII vyirH

the required entry is made, a stamp is applied, and letters or, if necessary, letters or characters are written on it when the toner image is fixed on the substrate.
In method step VIII shown in FIG. 9, a transparent film 6a made of a synthetic resin is applied b / w to the surface of the substrate 28. glued on, whereby they are passed between a pair of rollers 36a and 3F · "». If the film is then glued to the base or otherwise applied in this way, an identification card consisting of several layers is created. As already explained above, the protective layer can be applied in any way.

1 sheet of drawings

Claims (1)

Claim: Method for producing an identification card bearing an image of the holder, thereby characterized in that for the production of a electrostatic latent image formed by dots an image of the holder through a screen showing fine transverse lines is projected onto a charged, photoconductive layer, that the latent image on the photoconductive layer is in close contact with a pressure under pressure brought dielectric layer and thereby transferred to the dielectric layer that this transferred, electrostatic, latent image is developed into a visible toner image and then is fixed, and that after entering the required data on the dielectric layer the surface bearing the fixed image is firmly bonded with a transparent protective layer.